Female behavior drives the formation of distinct social structures in C57BL/6J versus wild-derived outbred mice in field enclosures

Background Social behavior and social organization have major influences on individual health and fitness. Yet, biomedical research focuses on studying a few genotypes under impoverished social conditions. Understanding how lab conditions have modified social organizations of model organisms, such as lab mice, relative to natural populations is a missing link between socioecology and biomedical science. Results Using a common garden design, we describe the formation of social structure in the well-studied laboratory mouse strain, C57BL/6J, in replicated mixed-sex populations over 10-day trials compared to control trials with wild-derived outbred house mice in outdoor field enclosures. We focus on three key features of mouse social systems: (i) territory establishment in males, (ii) female social relationships, and (iii) the social networks formed by the populations. Male territorial behaviors were similar but muted in C57 compared to wild-derived mice. Female C57 sharply differed from wild-derived females, showing little social bias toward cage mates and exploring substantially more of the enclosures compared to all other groups. Female behavior consistently generated denser social networks in C57 than in wild-derived mice. Conclusions C57 and wild-derived mice individually vary in their social and spatial behaviors which scale to shape overall social organization. The repeatable societies formed under field conditions highlights opportunities to experimentally study the interplay between society and individual biology using model organisms. Supplementary Information The online version contains supplementary material available at 10.1186/s12915-024-01809-0.

Over the last decade, multiple groups have developed high-throughput lab assays using modestly-sized arenas or interconnected cages that allow for increased complexity of social interactions [42][43][44].Yet, even relatively large and enriched lab settings [45][46][47] fail to capture many of the relevant features of social structures inferred by studies of wild mouse populations to be important to mouse natural history, such as territorial social organization and space use [48][49][50][51][52][53].Accumulating evidence suggests that generations of inbreeding and artificial selection in lab mouse strains has impacted their social behavior and interactions in small groups [48].Indeed, even simple lab behavioral assays can reveal differences in classical lab strain and wild-derived mouse behavior [54][55][56][57][58][59].But we have little understanding of the ecological validity of such studies on lab mice because of the lack of studies addressing the socioecology of lab mice under natural or semi-natural field conditions.At stake is not only our understanding of the ecological validity of studies of social behavior in constrained conditions, but also how we interpret and understand the difference between domesticated lab and genetically wild mice more generally.
An immediate solution is to study the social and spatial behavior of lab mice in large naturalistic spaces.Providing ample space for individuals to interact or avoid each other is critical for assessing social structures because it allows animals to freely express their preferences.There is a long history of studies utilizing semi-natural indoor or large outdoor enclosures to study the population biology of house mice under free-range conditions [60][61][62][63][64][65][66][67][68][69][70][71].These studies tend to use feral or wild-derived populations of outbred house mice and find that male mice establish and aggressively defend territories occupied by several females and their offspring.Fully adult males are most often associated with high quality territories, while juveniles and subadults typically aggregate in lower quality spaces within the environment [61,72,73].Adult females may compete for nest sites but form strong associations and may even co-nest with close relatives [74,75].The competitive environments generated under free-range conditions can have a strong impact on social behavior relative to the lab environment [65,76,77], motivating our study of mice in field enclosures where they can freely compete in a semi-natural environment.
Understanding how lab mice behave under more natural field conditions will inform how their behaviors have evolved relative to wild mice, providing a crucial piece of biological data for the best studied mammalian genotype, C57BL/6J (hereafter "C57").Here, we report the space use and social behavior of replicated mixed-sex populations of C57 and wild-derived outbred (hereafter "WD") mice in large outdoor field enclosures.We aimed to address three empirical questions with this study.(1) We sought to determine whether male C57 would establish and defend territories in the field, as opposed to generating societies with a single integrated dominance hierarchy (a common outcome in the lab [47,[78][79][80]).We also compare the territorial behaviors of C57 mice and WD outbred mice.(2) We sought to test whether space use and the resulting social relationships that form differ between C57 and WD outbred females.Female fitness in wild mice depends on their abilities to compete for nesting sites [61,74,81,82], and they show spatial and social biases toward other related females [75].We hypothesized that lab mouse husbandry practices, which regularly lead to isogenic females living and occasionally breeding at very high density [1], may have led to changes in the magnitude of social biases towards familiar females.(3) Finally, we sought to describe the social networks that emerged from these individual behaviors and how differences in behavior between C57 and WD mice scaled up to shape the larger social structure.We hypothesized that, despite the myriad complexities and idiosyncrasies of individual decisions and environmental fluctuations that influence societies, repeated studies of societies that differed in a salient manipulation-in this case the genotype of the individuals-would result in consistently different outcomes across treatments.If this hypothesis is correct, populations with similar initial ecological and demographic conditions will reliably generate similar social structures, suggesting that the biological basis of social organization is amenable to study.

Results
Over a 3-month period (June 2020-August 2020), we examined the emergent social organization generated in enclosures stocked with adult male (n = 10 per trial) and adult female (n = 10 per trial) C57 (n = 4 trials) and WD outbred house mice (n = 3 trials) over the course of 10-day trials.The study employed a common garden design and compared the behavior of C57 mice to wildderived house mice originating from upstate New York.All mice were bred and reared in the same lab colony prior to release.A detailed discussion of the study design, including the density of mice, length of trials, and genotypes tested is provided in the "Methods" section.Each field enclosure (38.1 m × 15.24 m; ~570 m 2 ) contained eight weather protected resource zones arranged in a 2 × 4 grid pattern (Fig. 1; Additional file 1: Fig. S1A-B), resulting in a slight excess of mice of each sex relative to the available resource zones.Mice were implanted with PIT tags and activity at the resource zones was monitored via an RFID antenna (see the "Methods" section).We obtained high density sampling of mouse RFID reads for all trials (1,307,712 ± 135,646 reads per trial; mean ± SEM) and a mean of 6771 ± 275 RFID reads per mouse per day.Mice were able to quickly traverse the distance between the zones despite the ground vegetation (minimum inter-zone travel time = 10 s; Additional file 1: Fig. S1D).We estimated individual mouse location for a total of 5653 h across all trials (mean = 808 ± 51 h/trial).On average, we inferred individual mice spent 4.2 ± 0.1 h/day at resource zones (range: 1.1 s-18.7 h).

Territory establishment is slower in C57 compared to wild-derived males
Territorial behavior is reported from wild mouse populations and field enclosure studies at moderate density or indoor environments with high physical complexity [63,72,[83][84][85].Territorial males attempt to exclude other males from the spaces that they control, and the ability to compete for and maintain a territory is a key driver of male fitness in freely mating mouse populations [70].In contrast, in laboratory and natural settings where there is low environmental complexity such that individual dominant mice can readily patrol most of the available space, an alternative social structure predominates where groups of male mice form a social dominance hierarchy [47,78,79,86].Mouse social hierarchies can vary in the extent of despotism or egalitarianism [47], though are generally characterized by a dominant alpha who is aggressive to all others and has broad access to space, followed by a linear hierarchy of subordinates [80].Commensal mouse populations may show a mixture of these social forms, with hierarchies formed among the males residing within a single territory or deme but are nevertheless characterized by restricted movement of mice between territorial spaces.
We sought to determine whether C57 and WD males in our enclosures formed territories or dominance hierarchies.If males form territories in our enclosures, a subset of the males in each trial would each monopolize one or more resource zones to the relative exclusion of others.What is more, no male would regularly access all resource zones.In contrast, if males establish Resource zones had a single entrance tube and food and water towers provisioned ad libitum.We observed a variety of behaviors in the resource zones including co-feeding between females, mating and courtship, social investigation, and male-directed aggression towards intruders.Top left image created with BioRender a dominance hierarchy within the enclosure, the topranking male or males are expected to have relatively free reign and regularly access all or nearly all resource zones.Consistent with previous field enclosure studies of wildderived mice [72], we find evidence that males of both genotypes established and defended territories, though the intensity of territorial behaviors was muted in C57 relative to the WD outbred mice.Three related, but distinct, analyses support this conclusion.First, males appear to establish monopolized spaces and rarely visit resource zones that they do not control (Fig. 2A; Additional file 2: Fig. S2A).By the third day, 93% ± 1 of all male-sourced RFID reads within each resource zone belonged to a single male, with zones in WD trials becoming monopolized by males more rapidly than in C57 trials over the 10-day period (t 500 = −2.93,P = 0.004; Fig. 2B).No individual male consistently accessed all or nearly all resource zones (range of mean daily zones visited = 1.0-3.9,median = 1.6).Instead, males spent the vast majority of their time within their single most visited resource zone, with WD males developing this site fidelity more rapidly than C57 males (t 67 = 2.31, P = 0.02; Additional file 2: Fig. S2B).Thus, male space use was consistent with territory defense, and inconsistent with a single integrated dominance hierarchy.
Second, males spend limited time in spatiotemporal overlap with other males.In all trials, males were placed into the enclosure within a resource zone along with their cage mate (brother).Males therefore overlapped in space at the start of the trials, but episodes of male spatiotemporal overlap rapidly decreased in both frequency (t 58 = −9.47,P < 0.0001; Additional file 2: Fig. S2C) and duration (t 2116 = −13.15,P < 0.0001; Fig. 2C).The collapse of previously existing cage mate relationships was remarkably rapid in WD males.At least half of all the estimated male dyadic spatiotemporal overlap time in WD mice elapsed in the first 54 min of a trial on average (range = 32-93 min), compared to 590 min on average (range = 210-1501 min; P = 0.02) for C57 males.Male-male spatial overlaps shortened in duration over the course of the trial more quickly in WD males as compared to C57 males (t 2116 = 2.77, P = 0.006; Fig. 2C) and were less frequent overall (t 27 = −4.14,P = 0.0003; Additional file 2: Fig. S2C), suggesting that the intensity of male-male competition in C57 may be weaker than in genetically wild mice.Strikingly, on days 5-10, when territories were clearly established, the amount of temporal overlap between a dominant territorial male in a given zone and other males that visited that same zone was 86% less than expected if each males' space use was independent of each other (range across trials = 74-97% less; t 6 = −58, P < 0.0001).This pattern could be explained either by (a) territorial males quickly expelling intruders when they co-occur or (b) non-territorial males biasing their visitation behavior to times that they expect the territorial male to be absent.
To characterize the variation in males' territorial behavior and resource access, we developed a priority access score (PAS) metric which tracked changes over time in the degree to which mice monopolized access to resource zones relative to same sex conspecifics (see the "Methods" section).Briefly, for the 10-day trials reported here, strongly positive final scores (near +10) indicate an individual consistently monopolized a single resource zone on each day of the trial while strongly negative scores (near -10) indicate an individual was consistently excluded from most spaces.High scores (>>10) indicate individuals who monopolized more than one zone over the course of the 10-day trial.Scores closer to zero indicate individuals that share spaces to some extent with other individuals of the same sex.Consistent with the hypothesized presence of territorial and non-territorial males, we find a bimodal distribution of males with high and low PAS values (excess mass test for unimodality: P < 0.02; Fig. 2D; Additional file 2: Fig. S2D; in contrast, females of both genotypes do not strongly monopolize resource zones at this density, see Additional file 3: Fig. S3B-C).
The third and ultimate indicator of territory formation rather than a single dominance hierarchy would be for contest outcomes to be predicated on spatial ownership.In other words, territorial males should win competitive interactions in their territory and lose in other males' territories, such that encounter outcomes depend on location.In contrast, under a social dominance hierarchy, a given male should win or lose depending on their rank without respect to location.To assess this prediction, we investigated male-male dyadic interactions within territories by identifying when the territory-holding male spatiotemporally overlapped with an intruder.For each such inferred overlap, we identified which animal was the first to leave the interaction (i.e., was displaced and lost acute resource access) and assigned that male as the "loser" of the interaction event.We assigned the male remaining in the zone as the "winner".
We identified 1380 two-male interactions which, as expected, overwhelmingly involved territory holders (n = 1290 events, 93.5% across all trials; mean = 25.6, median = 14, 95% C.I. [15.8, 35.2] per territory holding male).To compare win and loss rates for the same individuals, we examined 32 territorial males that were observed to engage in both "home" and "away" displacement events (n = 23 C57, n = 9 WD; n.b.-many territorial males were not observed in displacement events in an "away" context).We find that overall win rates of Fig. 2 C57 and wild-derived male mice establish territories rather than dominance hierarchies.A Males generally visited only one or two zones, and no males visited all zones, as shown by representative space use data from three C57 and three WD males (rows, as indicated by three letter individual identification codes).Each 2 × 4 grid shows the eight resource zones on each of the 10 days (columns) of a trial, with warmer colors indicating a high concentration of RFID reads in a given zone.B WD males form territories more rapidly than C57 males.Here, the y-axis represents the percent male-sourced RFID reads per zone from the focal zone's most present male, with values of 100% indicating complete monopolization.C Male-male dyadic spatiotemporal association bout events were shorter, less frequent, and deteriorated more quickly in WD mice compared to C57 mice.D To quantify territoriality, we calculated a priority access score, a cumulative metric of resource zone access across the 10 days of the trial.For both WD and C57 males, this territory metric deviated from unimodality, indicating a group of males that had consistent access to resource zones (territory holders) and those without (non-territorial).Here, scores near or greater than +10 indicate a male that controlled a resource zone for the duration of the trial.Negative scores are indicative of males that failed to capture a territory.E Consistent with territoriality, but not a dominance hierarchy, territory-holding males were much more likely to win a spatial dispute with another male, defined as displacing the other male, when the dispute occurred in their home territory as opposed to in a different male's territory.F Territorial control (as categorized by having a day 10 PAS > 0) conferred benefits in the form of increased access to females.This benefit of territoriality was stronger among WD as compared to C57 males (notice that WD males without a territory essentially never spend any time with females, dashed blue line).Data are plotted as means ± SEM territory holders at home (0.82 ± 0.03) are dramatically higher than win rates away (0.18 ± 0.05; t 31 = 12.19, P < 0.0001; Fig. 2E), with only one male showing a lower win rate at home than away.The one male that had an excess win rate away was observed to participate in only a single away displacement event, which he won.More than half of the males (59%, 19/32) lost all their contests when away from their territories.Winning away was most common when boundaries were still in flux; 72% (50/69) of displacement events won away occurred on the first day of the trial.Together, these results support the territory hypothesis and reject a hypothesis where male mice in the enclosures formed a single integrated dominance hierarchy.
Territorial control was associated with increased access to females.Males with positive (> 0) final PAS values spent more total time with females than males with negative (< 0) final PAS values over the course of the trial (t 661 = −3.6,P = 0.0004; Fig. 2F).The effect of territoriality on males' access to females was stronger among WD males.Among WD males, those with low PAS values essentially never spent any time with females (range of total time spent with females = 0.73-74.5 min), even on the first day of the experiment.In contrast, although C57 males with low PAS values spend dramatically less time with females over the course of the experiment as compared to high PAS males, they spend comparable amounts of time with females during the first day of the experiment, suggesting that the competitive exclusion of males from access to females was slower to develop in C57 mice.
Establishment of non-overlapping territories led to similar patterns of space use in both C57 and WD males.Examples of males' spatial behavior are shown in spatial heatmaps in Fig. 2A highlighting the spatial separation and fidelity of males in a single trial (see Additional file 2: Fig. S2A for full example trials).The males in each trial that were not able to capture a resource zone (those with priority access scores less than 0) appeared to adopt an alternative strategy in which they briefly visited several zones each day.These non-territorial males, who were not tied to a specific space that they needed to defend, tended to visit more zones over time on average as compared to the territorial males (t 65 = 2.61, P = 0.01; Additional file 2: Fig. S2F).

Distinct patterns of space use and social associations in C57 females
Studies of free-living house mice document competition among females for nesting space.Females tend to tolerate their relatives while avoiding or even showing aggression towards unrelated females [75,81,82,87].At the same time, male territorial structure may shape female behavior as novel males can lead to pregnancy termination through the Bruce effect [88,89] and novel males represent an infanticide threat [88][89][90][91].Competition for nesting space and avoidance of non-sire males is likely to be most acute among breeding females [71,92].Our data examine how females use space when first introduced into a large novel social environment and assess the extent to which their space-use behaviors are influenced by their social environment.
C57 females exhibited substantial differences in space and movement patterns across several measures compared to WD females as well as both male genotypes (Figs.2A and 3A; Additional file 3: Fig. S3A; Additional file 2: Fig. S2A).Unlike WD females and males of both genotypes, C57 female space use was not limited to a few neighboring resource zones, but instead was widespread across the enclosure space.Across sexes and genotypes, mice visited an average of 2.32 ± 0.11 resource zones per day over the course of the trial, though patterns of zone visits varied over time and among individuals.On average, the number of resource zones that animals visited each day increased as the trials progressed (t 133 = 13.3,P < 0.0001), but this increase was driven entirely by the behavior of C57 females (P = 0.52 for non-C57 females; Fig. 3B).Although all mice explored an equivalently low number of resource zones during the first several days in the enclosure, by the fourth day, C57 females had significantly increased exploration of the available zones compared to all other groups (P < 0.05 for daily LMM contrast estimates for days 4-10), which did not differ in their extent of space use.
Female house mice exhibit social preferences towards familiar same-sex conspecifics under free-living conditions [75,81], but the degree to which this happens in lab strains like C57 is unclear.Our results suggest that C57 females are more tolerant towards females in general and less biased towards familiar social partners.Overall, C57 mice engage in longer female-female spatiotemporal association bouts compared to WD mice over the course of the trial (t 11910 = −2.8,P = 0.02; Additional file 3: Fig. S3F).At the same time, the female preference for spending time with cage mates on days 2-10 of the trials was much greater in WD females than in C57 females (t 5 = 4.8, P = 0.005).WD females (t 5 = 7.2, P = 0.0007), but not C57 females (t 5 = 1.1, P = 0.33), differed significantly from the null value based on the number of cage mates present within a trial (Fig. 3D).Indeed, WD females spent nearly all their female-female social time with cage mates after day 2, whereas C57 females tended to spend less than half of their time with cage mates (Additional file 3: Fig. S3G).These results suggest that inbreeding and/or selection from lab mouse colony rearing practices may have a profound effect on both female space use and social behavior.

Repeatable differences in social structure between C57 and wild-derived mouse societies
Analyses of the behavior of each sex show generally similar patterns of space use for males but strongly divergent patterns for females.We next sought to understand how behavioral differences measured for individuals scaled up to larger patterns of social association and the emergent structure of societies.
We first examined how mice overlapped in space and time to determine to what extent individuals associated, as well as the range of spatiotemporal group Fig. 3 C57 females show distinct patterns of space use and social associations.A C57 females explore more of the available resource zone spaces than C57 males and WD males and females, as shown by three representative females from each genotype (rows, indicated by three letter individual identification codes).Each 2 × 4 grid shows the eight resource zones on each of the 10 days (columns) of a trial, with warmer colors indicating a high frequency of RFID reads in a given zone.B All sex and genotype combinations visit similar numbers of zones (unique per day) on the first several days of the trial, but C57 females increase the numbers of zones visited relative to any other sex or genotype combination as the trial continues.C C57 females visit more cumulative resource zones over the course of the trial period compared to all other sex and genotype combinations.D WD females show a strong and sustained preference for their cage mates, whereas C57 female preferences for cage mates quickly fall to null expectation levels (as indicated by the dashed line).Note that mice were placed in resource zones with their cage mates on the first day of the trial.Data are plotted as means ± SEM compositions that arose.For each trial, we estimated the time spent in group compositions of differing numbers of males and females (Fig. 4A).For this analysis, we considered each mouse's time separately such that a pair of mice in a zone together for 60 min is recorded as two mouse hours.
In each trial, mice were alone for most of the time that they were recorded at resource zones (range 50-64% for C57; 70-82% for WD mice, solitary mouse time per trial; P = 0.03 based on the probability of all four C57 trials having the lowest values; Fig. 4A), but the proportion of time that individuals spent alone was strongly predicted by sex and genotype.On average, males spent a greater proportion of recorded time at resource zones alone than females (t 1339 = 5.4,P < 0.0001; Fig. 4B).Overall, WD males increased their time alone over the course of the trial (t 1339 = −3.1,P = 0.002; Fig. 4B) and were especially likely to spend time alone compared to all other groups; all of them (29/29) spent more than 50% of their total recorded time alone.In comparison, 83% of WD females (25/30), 78% of C57 males (31/40), and only 18% of C57 females (7/40) spent most of their recorded time alone.Given the interest in the biology of social isolation in mice [93][94][95][96][97], it is notable that when given the opportunity to freely interact, many mice spent a significant portion of their observed time alone over the course of their trial.
Though individuals spend a large portion of their time at the resource zones by themselves, we estimated more than 2000 mouse hours of spatiotemporal associations across the seven trials, defined as time with two or more mice at the same zone simultaneously (Additional file 1: Fig. S1F).Dyadic interactions accounted for > 50% of estimated association time in both genotypes (62-80% in C57, 78-86% in WD), though larger aggregations of mice were detected in all trials (Fig. 4A).On average, females spent a greater portion of their recorded time in samesex associations than males over the course of the trial (t 1339 = −6.5,P < 0.0001; Additional file 4: Fig. S4A).Most mice (77%, n = 103/134) spent > 50% of their recorded association time in opposite-sex groups, with males increasing this metric over the course of the trial relative to females (t 1165 = 6.6,P < 0.0001; Additional file 4: Fig. S4B).
To investigate the emergent group structure of both genotypes, we analyzed the total and daily social networks formed for each trial.Overall, C57 mice formed more connected networks than WD mice, a difference which was largely driven by high levels of C57 female sociability (Fig. 4D-E).WD networks increased in the number of graph components-the portions of the network disconnected from each other-over time (t 61 = 4.86, P < 0.0001; Fig. 4F), echoing the demic structure reported for many wild mouse populations [52,98,99].In contrast, C57 networks became more connected over the course of the trials.Over time, the network edge density-a measure of the proportion of edges actually observed out of all possible edges in the network-increased in C57 social networks, but not in WD networks (t 61 = −5.4,P < 0.0001; Fig. 4G).Notably, the two genotypes show completely non-overlapping distributions for network edge density from days 4 to 10 (P = 0.03, non-parametric, each day).The differences between genotypes reported in this section are based on whole network level metrics indicating that the basic overall structure of social organization differs between the genotypes.
Females of both genotypes had high degree centrality measures compared to their respective males, indicating females encountered more unique social partners on each day of the trial.There was a significant three-way interaction between sex, genotype, and time, such that C57 females rapidly increased their network centrality measures compared to all other sex and genotype combinations (t 134 = 2.6, P = 0.01; Fig. 4H).Thus, many of the differences we see in social networks between the genotypes is driven by the propensity of C57 females to cooccur with many distinct individuals.By the final day of the trial, C57 mice had overlapped with many more of (See figure on next page.)Fig. 4 C57 social structures are more interconnected than those in wild-derived mouse societies.A C57 mice spend less time alone and have larger numbers of social participants in association events as compared to WD mice.The contour plot shows the average duration of observed time spent in different male and female group compositions across trials for C57 (left) and WD (right) mice.The numbers reported here are the average number of hours estimated per trial.B C57 females spend less than half of their total observed time alone throughout the trial, less than any other group.C Strain and sex combinations decrease the time spent in same-sex groups over the course of the trial, with males of both strains spending minimal amounts of their observation time in same-sex interactions.D, E Daily social networks from an example C57 trial (D) demonstrates a typical pattern of persistently high female interconnectivity while an example outbred trial (E) demonstrates increasing network modularity over time.The size of connections between nodes represents the edge weight whereas the size of nodes reflects the node edge strength or the sum of all edge weights for a single node.F Number of network components increases in WD, but not C57, social networks over time.G Network edge density increases in C57, but not WD, social networks over time.H C57 females have consistently higher measures of node degree centrality, indicating that they are consistently meeting large numbers of social partners on each day of the trial, relative to other sex and strain combinations.Data are plotted as means ± SEM the available social partners present in the enclosures as compared to WD mice (t 5.48 = −3.9,P = 0.01; Additional file 4: Fig. S4C), who failed, on average, to ever meet more than 50% of the potential social partners, at least within or around resource zones.Intriguingly, females of both genotypes showed high levels of vertex page rank scores, indicating that females of both strains maintain higher levels of connectedness over time than their respective males (t 1343 = 3.2, P = 0.001; Additional file 4: Fig. S4D).

Discussion
Our replicated semi-natural field enclosure experiments demonstrate that C57BL/6J lab mice broadly recapitulate many of the behaviors of wild-derived outbred mice in free-ranging conditions, including clear evidence of male territories, but have different emergent social structures.This difference is largely due to C57 females being more exploratory and showing less biased patterns of social association.The organization of mammal societies is influenced by ecological [100][101][102], demographic [103][104][105][106], and phylogenetic factors [107][108][109], each of which were controlled for in our trials.Thus, these data show that genotype can have a strong effect on social structures in mammals [110,111].In this case, it demonstrates key social behaviors that have been altered during the process of lab mouse domestication [48].These data also highlight the flexibility of mouse social behaviors across diverse ecological and demographic conditions.For example, in contrast to lab studies at high density, which identify dominance hierarchies among both lab and wildderived male mice [46][47][48]112], the males in our lower density populations consistently formed and defended territories regardless of genotype (Fig. 2).
Although our experiment only examined one set of ecological and demographic conditions, it demonstrates a tractable field approach in which variables including food resources, defensibility of spaces, and demographic compositions are all easily tunable.There has been considerable interest in recent years in high-throughput measures of mouse social behavior in lab settings [42,[44][45][46]113], and our study provides a blueprint for similar studies to be conducted under semi-natural outdoor settings using different socio-ecological conditions or genotypes.Studying reproducible genotypes of mice under similar settings in other locations and seasons provides an exciting avenue to examine the role of environmental variation in shaping individual phenotypes and population dynamics.
What drives the difference that we saw in female space use across our trials (Fig. 3)?Space use in female mammals is often predicted by intra-sexual competition for food resources and nest sites [114], but resource availability and population density were identical across trials in our study.This suggests two non-mutually exclusive possibilities.First, there may be a genetic difference shaping space-use behavior between C57 females and wild-derived outbred females.For example, this could be manifest as an increased tendency to explore irrespective of their social environment.Alternatively, female behavior may respond to the social conditions present in our trials, which differ in some key respects between the two genotypes.C57 females experience a society where everyone has very high genetic similarity, while WD females experience a world with variation in relatedness.It is likely that mouse behavior in general might be sensitive to these parameters, though studies of social interactions in the lab frequently utilize single inbred strains of mice [115][116][117].Female mice respond to variation in perceived relatedness between themselves and males [68,118,119], and thus it may be the case that females explore more in conditions when all social partners are genetically homogeneous but show more restricted space use when social partners are genetically heterogenous.In wild house mice, infanticide risk from both male and female conspecifics is thought to be a major driver of social behavior in females [120][121][122].As a result, wild female house mice will aggressively defend space from other females [71,81,82,123,124].In contrast, C57 mice have been bred to live in cages at high densities, especially among females, and this is associated with lower female aggression compared to wild-derived mouse genotypes [125].Differences in relative tolerance of other females may be a key driver of the observed differences in social organization between C57 and outbred females in this study.Understanding how innate behavioral differences among genotypes and emergent properties generated by social interactions shape mammalian societies is an exciting future direction, one that could be extended to other commonly commercially available inbred (such as BALB/c) and outbred (such as Swiss Webster and CD-1) mouse strains.
Male space use in rodents and other mammals is frequently linked to patterns of female space use [114,122].Yet, despite differing patterns of female space use between genotypes, the male spatial and social structures across genotypes were quite similar, highlighting that some aspects of social organization are relatively less sensitive to other features of a population's socioecology.Perhaps one of the most striking features of our study is the speed with which male-male social interactions decrease in frequency, especially among wild-derived outbred males (Fig. 2C).Previous studies of wild mouse behavior have reported males will defend territories and attempt to exclude other males [60,64], and our data show this behavior is retained in male C57 mice.The formation and physiological consequences of dominance hierarchies among male mice have been the subject of recent study in the lab [47,48,112,126], but our results suggest that when given ample and defensible spaces male mice will tend to avoid interacting with others and form individual territories rather than a single integrated dominance hierarchy.Differences between territoriality and dominance behaviors remain poorly understood at the mechanistic level.Social dominance hierarchies and the establishment of territorial boundaries could be mediated by the same physiological and neurological mechanisms, or they might be mediated by distinct mechanisms.The process by which dominant males recognize known, tolerated subordinates may be fundamentally distinct from the process by which a territorial male characterizes intruders as well as neighbors versus strangers [127,128].
Across repeated trials, we identified differences in the higher-level social organizations of C57 lab mice and their wild-derived outbred counterparts (Fig. 4).Studies of social structures tend to come from idiosyncratic populations living in the wild, meaning that studies of social behavior in natural conditions are rarely replicated [129][130][131].Studies of free-living populations are critically important, but this non-replicability makes understanding the specific genetic, neurobiological, ecological, and demographic factors influencing complex behavior challenging.The repeatability of social organization demonstrated here suggests that future work manipulating aspects of physiology or neural function in free-range mice will offer a unique opportunity to study not just differences in individual behavior, but also how and whether specific behaviors reliably influence society.

Conclusions
The importance of social interactions in shaping health, physiology, and fitness is increasingly recognized, though traditional biomedical approaches study animals in highly impoverished social conditions.Thus, approaches for studying animal models in more natural and free-ranging settings are needed as a complement to traditional laboratory studies that examine animals in highly socially and spatially constrained conditions.Using a classic common garden study design, we investigated the spatial and social behavior of the best studied genotype of mice in comparison to wild-derived outbred counterparts.We found that while male C57 and WD mice behavior was largely similar in that males of both genotypes formed and defended exclusive territories, male C57 mice did so less rapidly.Importantly, territoriality in our field enclosures was the observed social organization, in contrast to a dominance hierarchy which is more commonly found in studies of mice in laboratory environments.Female C57 mice differed strikingly from their wild-derived counterparts in terms of their increased exploration of the field enclosure, their time spent in association with other mice, and their lack of preference for spending time with previously known same-sex cage mates.Moreover, we show that these differences scale to profoundly shape the larger social networks formed by populations of C57 and WD mice, with C57 networks being persistently highly connected across days.These results indicate that the process of domestication in laboratory mice and selection for social tolerance among females may have profound impacts on the expression of group social behaviors and broader patterns of lab mouse societies.Consistency in individual and overall society-level differences within and between genotypes suggests that the wealth of genetic resources available in mice make them well-suited to address fundamental questions about the genetic basis of higher-level social organization.

Ethical note
All experimental procedures adhered to guidelines established by the U.S. National Institutes of Health and the ASAB/ABS guidelines for the use of animals in research [132] and have been approved by the Cornell University Institutional Animal Care and Use committee (IACUC: Protocol #2015-0060).All animals were briefly anesthetized and implanted with dual PIT tags (12 mm) prior to introduction to the field enclosures.This procedure is minimally invasive and is consistent with recommendations by the veterinary and animal care staff at Cornell University.PIT tag weight is negligible, and anesthesia removed any discomfort associated with handling and implantation of the tags.We observed no changes in mouse behavior as a result of this procedure, as assessed by normal food and water intake and daily activity on home cage running wheels.

Animals
We examined two groups of M. m. domesticus, C57BL/6J (C57) and wild-derived (WD) outbred mice.Rather than merely qualitatively comparing our data to published data on mouse behavior in field enclosures or semi-natural indoor settings [51,63,72,133,134], we conducted identical, simultaneous trials using wild-derived outbred mice to allow for a direct quantitative comparison of data collected using the same methods and the same physical environmental conditions.We note that while lab mouse ancestry includes three house mouse subspecies, the C57 genome is > 90% Mus musculus domesticus [135].More information on the origins of C57 mice can be found elsewhere [136][137][138][139]. Therefore, as a "control" wildderived mouse population, we used outbred mice derived from wild house mice caught in upstate New York.Thus, the comparison group of mice were born and raised in the lab for multiple generations but have a wild-derived outbred genetic background, following other studies examining genetically "wild" house mouse populations [48,64,85,125].We initially obtained C57 (#000664) mice from The Jackson Laboratory (Bar Harbor, Maine, USA), which were then maintained and bred in our colony until the start of the experiment.We maintained a wild-derived outbred mouse stock from intercrossing six different wild-caught families generated through distinct initial pairings of wild mice from Saratoga Springs, NY, USA, trapped by MJS in 2013 [140].Thus, the potential adverse stressful effects of transferring wild-caught mice to laboratory environments for use in our enclosure study is avoided.We maintained an outbred colony with > 16 breeding cages prior to the start of the experiment in 2020.These mice are descended from the same initial collection in Saratoga Springs that gave rise to the wildderived inbred mouse strains SarA/NachJ (#035346), SarB/NachJ (#035347), and SarC/NachJ (#035348) available from the Jackson Laboratory [141].However, our mice are not descended from the wild-derived inbred strains deposited at JAX, rather they are simply related to them and share alleles from the wild Saratoga Springs, NY house mouse population.All of the wild-derived outbred mice in our experiment had unique diploid genotypes representative of wild house mouse haplotypes found near Saratoga Springs, New York.All of the mice (both C57 and wild-derived outbred) used in this study were bred in our lab colony, under standard housing conditions contemporaneously in the same room.All mice were between 15 and 28 weeks of age when they were released into the field enclosures (see Additional file 6: Table S2 for detailed information on the ages and litter relationships among mice).
The population density in our enclosure was 0.034 mice/m 2 , which falls within the range of typical population densities reported for wild mice [142] (~0.0011-0.11mice/m 2 ) and is the same order of magnitude as initial populations in other field enclosure studies of wildderived mouse behavior [63,68].

Study design
Field studies of wild populations provide a powerful means to link aspects of organismal biology to selection but are typically hampered by a lack of replication [129,143].Enclosure studies done over short, but biologically relevant, time periods provide an opportunity to observe replicate populations across multiple trials.A fundamental feature of enclosure studies, as compared to wild populations, is that the experimenters must choose among a range of possible resource distributions, population densities, sex ratios, etc. as the starting conditions of the trials.House mice naturally live under a wide range of resource distributions and densities across non-commensal and commensal settings [61,66,73], meaning that there exists a large set of naturalistic conditions rather than a single most appropriate condition for studying mice.While studying social organization across a range of socio-ecological starting conditions will be informative, for this study, we chose a single common set of initial resource distribution, density, and sex ratio conditions for all trials.For our trials, we released 10 males and 10 females into semi-natural field enclosures with eight resource zones which we monitored using a commercially available RFID system.This experimental design allowed us to assess the consistency of social behaviors and structures formed within the enclosures across replicates and to isolate the effect of host genetic background on these outcomes.
To initiate each trial, we placed mice implanted with passive integrated transponder (PIT) tags (see RFID analyses section) into one of eight resource zones (see the "Field site" section) with their same-sex sibling cage mates in the evening shortly before sunset, meaning that all individuals started the trials at a resource zone with one or more familiar social partners (see the Additional file 6: Table S2 for details on cage mate and relatedness information).We allowed trials to proceed for 10 days.This trial length was chosen because it allowed us to avoid females giving birth in the enclosures and made it feasible to conduct multiple replicated trials in the same enclosures over the course of a single summer.House mouse social structure has been reported to vary seasonally and with shifts in demographic parameters in natural populations [49,134,144], so different conditions or studies conducted at other times of year may yield different results.The experiment reported here focuses on behavior during the initial formation and establishment of social structures within replicated mouse populations in our enclosures while controlling for seasonal and demographic variation.Over the course of 10 days, mice explored the enclosures and resource zones and engaged in a variety of social interactions with conspecifics including courtship, mating, co-nesting, and fighting (Fig. 1; Additional file 7: Video S1).As our goal was to test hypotheses regarding patterns of mouse space use and social structure, we focused our analyses on the large RFID dataset.

Field site
We conducted field work at Cornell University's Liddell Laboratory Field Station in Ithaca, New York, USA using two adjacent and identically sized outdoor field enclosures.Our enclosures are approximately 9,000 times larger than the area of a standard laboratory mouse cage (Additional file 1: Fig. S1B).The walls of the enclosures were made from sheet metal and stood approximately 1.2 m tall and extended 1.2 m into the ground to prevent the mice from tunneling and moving between the enclosures.Each enclosure was covered with netting to prevent aerial predation, and gravel was spread along the interior perimeter of each enclosure to discourage digging near the walls.Three days prior to releasing mice into the enclosures, we trapped in and around the enclosures to capture and remove any small mammals or snakes from the enclosure.The enclosures contained a mixture of local perennial grasses and plant communities which were mowed to a height of approximately 5 cm at least one day prior to the start of each trial to maintain similar ecological starting conditions across trials.
We supplied all resource zones with food and water accessible by the mice ad libitum.Resource zones were covered with waterproof corrugated roofing material attached to a polyvinyl chloride (PVC, Home Depot, USA) frame to shade the zones during the day and provide protection from rain.Resource zones were comprised of two nested storage tubs (Rubbermaid, USA) and a single PVC entrance tube (50 mm diameter) through which the mice could freely enter or exit the zone.Each resource zone contained feeder towers containing food and water in excess (approximately 50 g of mixed sunflower and bird seed, and 2 L of water), which was replenished within a trial as necessary and replaced between trials.Several pieces of plastic lumber were added to provide edges and elevated locations for the mice to perch within the resource zones.All resource zone materials were thoroughly washed with soap and water and then wiped down with 70% ethanol at the start of the trial and again once all mice were removed from the enclosure to remove to prevent the transfer of odorants between trials in these spaces.
At least 24 h prior to release in the enclosures, all subjects were briefly anesthetized with isoflurane (3-5%) and placed into a stereotaxic frame (Kopf Instruments, Tuhunga, CA, USA).Mice were subcutaneously implanted with dual PIT tags (BioMark, Boise, ID, USA) in the dorsal flank and periscapular region.Each resource zone was equipped with a 15 cm RFID antenna connected to a centralized data acquisition unit (BioMark, Small Scale System, Boise, ID, USA).Antennae were placed directly beneath the floor adjacent to the PVC zone entrance tubes to increase the likelihood of capturing mouse activity during entrances and exits from the resource zone.Scanning for PIT tags within the antenna range occurred at approximately 2-3 Hz continuously for 10 days.
After the 10-day observation period, > 50 live-catch traps (H.B.Sherman, Tallahassee, FL, USA) were baited with nesting material, sunflower seeds, and a moistened cotton ball and placed in a grid pattern in the enclosures in the evening (1900-2200 h) and were checked for occupancy the following morning (0600-0900 h).Trapping continued until all the mice were recovered or identified as deceased or missing (a conclusion reached if there were no RFID reads in the enclosure for a 24-h period after 3 days of trapping; see the Additional file 6: Table S2).The trap locations were recorded, and the individual identities of the mice were confirmed using a handheld RFID reader (BioMark, HPR Lite).Mice were immediately transported to a clean cage with ample nesting material, sunflower seeds, and water.At the conclusion of the experiment, all mice were euthanized using carbon dioxide inhalation followed by decapitation for the collection of tissues for future analyses.

RFID analyses
We monitored the resource zones continuously over the trial period via a RFID antenna placed beneath the sole entrance into the zone (Fig. 1; Additional file 1: Fig. S1C).Since the RFID antenna detected tags both above and below the horizontal plane of the antenna and mice moved underneath the resource zones, we inferred RFID reads to indicate that mice were within a space inclusive of the inside and underside of the storage tubs.
To convert instantaneous RFID reads into estimates of how long mice spent at the resource zones, we grouped RFID reads into discreet resource zone visits with estimated durations (Additional file 1: Fig. S1E-F).As expected, the total number of visits to a zone strongly correlated with the total estimated duration of time spent at a zone (Spearman's correlation, R > 0.84 for all genotype and sex combinations; Additional file 1: Fig. S1G).
We conducted two types of RFID analyses focusing on (1) when and at what zone each mouse was detected and (2) estimating how long it spent at each zone.In the first set of analyses, we examined whether or not mice visited a given zone during each day of the trial (Figs.2A  and 3A-C; Additional file 1: Fig. S1G; Additional file 2: Fig. S2A&F; Additional file 3: Fig. S3A).We estimated the minimum distance traveled using consecutive transitions in the RFID reads between antennae in different resource zones and the known spatial layout of the enclosure (Additional file 3: Fig. S3D).To assess the degree to which resource zones were exclusively accessed by individual mice, we examined the percent of same-sex sourced RFID reads in zones for each mouse (Fig. 2B).
In our second set of analyses estimating the durations of time mice spent in zones, we first examined the time elapsed between consecutive RFID read events for each mouse within each resource zone (the RFID interread interval).We found that the distribution of all RFID inter-read intervals was heavily skewed (min = 1 s, median = 1 s, mean = 16.4 s, max = 32,683 s; Additional file 1: Fig. S1E).We grouped RFID reads for each mouse for each zone into visitation bouts using a 139 s (the cut-off for capturing 99% of all the within-mouse interread interval values within a single zone) sliding window method such that an RFID read which occurred within 139 s of the previous read extended the visit bout duration up to that read.Transitions between zones automatically ended and started bouts in the first and second zones, respectively.We assigned isolated single RFID reads (with no other reads within 139 s before or after the focal read) a visit bout duration of 1 s.Using this dataset, we estimated the time mice spent in resource zones (Additional file 2: Fig. S2B).Mice were defined as participating in a spatiotemporal association bout when two or more mice had overlapping resource zone visit bouts within the same zone (see Additional file 1: Fig. S1F for a graphical schematic of the approach).We used the spatiotemporal association bout dataset to estimate the duration and frequency of male-male (Fig. 2C), femalemale (Additional file 2: Fig. S2E), and female-female (Additional file 3: Fig. S3F) dyadic association bouts.We omitted a subset of animals from a subset of days for all spatial and social analyses when they received no reads over multiple days and were presumed dead (see Additional file 6: Table S2).

Priority access score calculation
Priority access scores were calculated separately for male and female mice within a trial.First, we calculated the time a given mouse (M) occupied a resource zone (Z) as a percentage of the total time that zone was occupied by same-sex conspecifics on a given day (D).
Next, we calculated a daily Capture Score by summing the Occupancy values for all available zones.Mice that did not have an occupancy value of greater than 0.5 (in other words, a majority share of the time spent in any zone), were penalized by subtracting 1 from the final Capture Score.The penalty indicates that on a given day, a mouse failed to capture any of the zones that mouse visited.
To see how access to zones changed over time, we took the cumulative sum of an individual's Capture Score As an example, if one male (male A) occupied a single resource zone every day of the trial for 4 h a day, while another male (male B) accessed only that same zone for 1 h per day, and the zone was visited by no other mice, male A's daily Capture Score would equal 0.8, (because he controlled 4 out of 5 h), while male B's daily Capture score would equal − 0.8 (because he controlled 1 out of 5 h and received a one-point penalty for not controlling any zones).If this pattern of visitation remained unchanged for all 10 days, then male A's final priority access score would equal 8, while male B's priority access score would equal − 8.The priority access score value thus provides a temporally evolving measure that captures the dynamics of territory formation, maintenance, and collapse (Additional file 2: Fig. S2D; Additional file 3: Fig. S3B).

Male spatiotemporal overlap and win/loss at home and away
We used the zone visit bout and spatiotemporal association bout dataset to investigate the degree to which territorial and intruder males avoided spatiotemporal overlap.Across all zones for the last six days of the trial, we independently calculated the total time territorial and intruder males spent in zones and the amount of that time that was spent in spatiotemporal overlap.We derived null expected values of territorial and intruder male spatiotemporal overlap ((total territorial male hours in zones × total intruder male hours in zones)/ (24 h × 6 days × 8 zones)) and examined the percent difference between the null expectation and the observed time territorial and intruder males overlapped.We chose the last six days of the trials for this analysis as territorial relationships were clearly established by this point in the trial.
Next, we used the RFID and spatiotemporal association bout data to estimate the dynamics of male spatiotemporal overlap and territorial intrusion.We inferred contests by identifying instances in the dataset where a single male within a zone was joined by an additional Priority Access Score M,D = D d=1 Capture Score M,d male, followed by one of the males leaving.We identified the male participants as either the territory holder of that zone or as an intruder based on whether the focal male had captured > 50% of all of the male-derived RFID reads within the zone during the last 24 h.We derived "win" and "loss" rates both within and away from a home territory for each male participant on each day of the trial by assigning the remaining male and the male that left as the "winner" and "loser" of the contest, respectively (Fig. 2).

Female spatiotemporal overlap and cagemate associations
Using the known cage mate relationships between individual females, we examined the total time female mice spent in spatiotemporal association with cage mate (sibling) versus non-cage mate females (Additional file 3: Fig. S3G).Based on the number of cage mates and noncage mate female social partners available on each day of the trial (which fluctuated for some trials based on mice disappearing from the trials, see the Additional file 6: Table S2), we calculated a daily null value of the expected time spent with cage mates and the percent observed value deviation from the expected separately for each female (Fig. 3D).

Social network analyses
We used the spatiotemporal association bout data set arranged in a group by individual matrix to construct social networks.Daily weighted adjacency matrices were derived from a Simple Ratio Index calculation based on counts of binary participation in spatiotemporally overlapping mouse zone visit bout events (where zero indicates that individuals were never in the same spatiotemporal association bout and one indicates that individuals shared all spatiotemporal association bouts; Additional file 1: Fig. S1F) using the asnipe [145] package in R 4.1.2(R Development Core Team).All networks were constructed using the weighted matrices and the igraph [146] package in R. Node sizes in our network reflect the node edge strength, or the sum of all connected edges to the node, while edge widths reflect the edge weight derived from the daily weighted adjacency matrices.If an animal died or went missing, we no longer included it in a given trial's daily network [147,148] (see Additional file 6: Table S2).

Statistical analyses
We built mixed effects models using R 4.1.2(R Development Core Team) and the R packages lme4 [149], lmerTest [150], and emmeans [151] to examine relationships between predictor and response variables.We include the full statistical tests and model outputs for all analyses in the Additional file 6: Table S2.Most analyses are conducted with a repeated measures design where data are examined for each day per mouse or other relevant unit as appropriate using mixed effects models.Across models we considered random effects of trial, mouse, and/or time in the trial.We included relevant random intercepts and random slopes in our models as appropriate-random slopes of time were generally included, but we occasionally needed to simplify random effects structures when necessary to avoid singular fits.All model formulae, including random effects structures, are explicitly reported in Additional file 5: Table S1.For testing for unimodality, we used the multimode [152] package with "ACR" method [153].Graphing was done in R using the package ggplot2 [154] and in GraphPad Prism 9.3 (www.graph pad.com).We report all means ± standard error (SEM), unless otherwise stated, and consider all values statistically significant when P < 0.05.

Fig. 1
Fig.1Experimental design for replicate populations of C57 and wild-derived mice in field enclosures.Photos demonstrate the layout of the field enclosures and the eight resource zones arranged in a two by four grid pattern.Resource zones had a single entrance tube and food and water towers provisioned ad libitum.We observed a variety of behaviors in the resource zones including co-feeding between females, mating and courtship, social investigation, and male-directed aggression towards intruders.Top left image created with BioRender

8 z=1
if ∃ Occupancy M,D,z > 0.5 ∀ z = 1, . . ., 8Occupancy M,D,z − 1 otherwise ordinally across each day of the trial to derive an evolving priority access score on each day of the trial.